Student Abstracts

Oxygen isotope ratios (¹⁶O/¹⁸O) have been used in numerous studies of mantle lithologies to estimate 1) the protolith 2) the source of metasomatizing fluids, 3) temperature of formation, and 4) degree of equilibration between coexisting minerals. The δ¹⁸O value of mantle olivine comprises a very restricted range (Mattey et. al., 1994), so that even subtle deviations from this ‘canonical’ value indicate some form of contamination. Eclogites span a range of 2–8‰ and suggest an altered oceanic crust or sediment protolith (MacGregor and Manton, 1986). However, the ¹⁸O/¹⁶O information alone provide limited information. The addition of the novel ¹⁷O/¹⁶O ratios provide additional constraints on mantle minerals, expanding the isotope data from a one-dimensional line to a two-dimensional field.

Our preliminary results demonstrate the utility of triple oxygen isotope analyses of mantle materials. OPX and olivine mineral separates from spinel peridotites are generally well-behaved for ¹⁷O, with Δ' ¹⁷O values (see Sharp, 2013 for nomenclature) of -0.05 ± 0.01‰, the same as presumed mantle olivine. We see that CPX is out of δ¹⁸O equilibrium in all cases. The Δ¹⁸O values for olivine, garnet, OPX, CPX and phlogopite from a granular garnet peridotite (Kimberley, SA) suggest complete ¹⁸O/¹⁶O disequilibrium, but the Δ' ¹⁷O values of all samples are again typical of that of the average mantle. In contrast, a sheared peridotite from the same location has Δ18O values in equilibrium at ~950 °C, but Δ' ¹⁷O values that suggest mixing between a low Δ' ¹⁷O – low δ¹⁸O and a high Δ' ¹⁷O – high δ¹⁸O component. One mantle eclogite sample, a grospydite from Smyth and Hatton (1977), has a wide range of Δ' ¹⁷O values but δ¹⁸O values that appear in equilibrium. It has been suggested that the wide range in δ¹⁸O values could suggest an origin for the eclogites from subducted altered oceanic crust (MacGregor and Manton, 1986). We are measuring the triple oxygen isotope values of altered oceanic crust in order to identify potential sources for the ¹⁷O isotope disequilibrium seen. The Δ' ¹⁷O values of these samples can be used to support such an idea. In general, the Δ' ¹⁷O values of altered oceanic crust are higher than typical mantle. Low Δ' ¹⁷O values may be indicative of subducted sedimentary material.

In some regions of the Arctic, sea ice decline and the resulting loss of foraging opportunities have been associated with recent reductions in polar bear abundance, survival, and reproduction. It is often assumed that during food deprivation lipid reserves (e.g., adipose fat) are the limiting factor to polar bear survival, and the role of protein reserves (e.g., skeletal muscle) is often under appreciated. Structural tissues require a constant input of amino acids for maintenance; to provide these amino acids, fasting bears catabolize endogenous protein, potentially at a greater rate than endogenous lipid. Recent studies with captive vertebrates demonstrated that when feeding, animals may use carbon derived from dietary lipids to synthesize proteins used to build structural tissue. We hypothesize that fasting polar bears use a similar process to transfer carbon from stored adipose fat to stored protein. To test this hypothesis, we are using amino acid carbon isotope (δ¹³C) analysis, and archived samples from a previous study of nutritional ecology in the Southern Beaufort Sea, to track carbon flux between protein-rich (red blood cells, serum, skeletal muscle) and lipid-rich (adipose) tissues in individual, free-ranging polar bears that exhibit a spectrum of body condition and feeding status. Our preliminary data suggest that a portion of the non-essential amino acids in red blood cells of fasting polar bears were newly synthesized with carbon that had been transferred from endogenous adipose tissue. If carbon movement between lipid and protein is substantial, it will change our understanding of polar bear fasting physiology and endurance, influencing forecasts of how this species will respond to continued ice loss.

The presence of water in martian meteorites provides a unique glimpse into the evolution of water on Mars. Previous studies have shown that the oxygen extracted from water in martian meteorites is generally not in isotopic equilibrium with the bulk silicate rock. By analyzing the isotopic composition of oxygen in the water extracted from a variety of martian meteorites we hope to identify distinct oxygen isotope reservoirs on Mars (mantle, crust and hydrosphere), and attempt to link them to certain geological processes experienced by the different types of martian meteorites. The pioneering work by Karlsson et al. (1992) has thus far been the only systematic study of oxygen isotopic compositions of water extracted from martian meteorites and their data cannot be easily interpreted. A broader and more detailed sampling is the goal of this study. So far we have measured the oxygen isotope composition of water extracted from martian shergottites Tissint and Zagami and are presently working on analyzing other shergottites as well as a variety of nakhlites, chassignites and the basaltic breccia NWA 7034. Water was extracted from samples using stepwise heating and converted to O₂ by fluorination. The O₂ gas was then purified in a GC column and measured for the triple oxygen isotope value. Δ¹⁷O' values of water extracted from Tissint and Zagami are distinctly elevated relative to that of Earth but are lower than the corresponding bulk rock Δ¹⁷O' values (0.33‰). This supports the previous observations [2,3] of isotopic disequilibrium (or terrestrial contamination) between the two sites of oxygen (water and bulk rock). Both samples also show a similar trend in the Δ¹⁷O' values of the waters released at different temperature steps. The lowest Δ¹⁷O' values (<0.1‰) are measured in waters extracted below 150°C. This is likely due to terrestrial contamination of the absorbed water portion. The highest Δ¹⁷O' values were measured for water extracted between 200 and 400°C (0.21‰ for Tissint and 0.1‰ for Zagami). At temperatures above 400°C the Δ¹⁷O' values of the extracted water begin to get more negative (0.17‰ for Tissint and 0.09 for Zagami). Since both Tissint and Zagami were observed falls, we would not expect extensive terrestrial contamination, although trace amounts of hydration could affect the 'water' data, but not the bulk rock data. The existence of heterogeneity in the Δ¹⁷O' values of water extracted at different temperature intervals from Tissint and Zagami supports the possible existence of isotopically distinct reservoirs on Mars. To better understand the origin of the waters in these meteorites, we are currently working on understanding the mineralogical constraints on storage and release of water. The Δ¹⁷O' trend observed in water extracted from Tissint and Zagami will be further evaluated as we continue to expand the body of data on the oxygen isotopic composition of water in martian meteorites.